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Imagine we have an alphabet of, say, 5 chars: ABCDE.

We now want to enumerate all possible sets of 3 of those letters. Each letter can only be present once is a set, and the order of letters doesn't matter (hence the letters in the set should be sorted).

So we get the following sets:

  1. ABC
  2. ABD
  3. ABE
  4. ACD
  5. ACE
  6. ADE
  7. BCD
  8. BCE
  9. BDE
  10. CDE

For a total of 10 sets. The order is lexicographical.

Let's now assume that the alphabet length is N (5 in this example) and the length of the set in M (3 in this example). Knowing N and M, how could we, if at all possible:

  1. Tell the total number of combinations in at worst O(M+N) (the answer is 10 in this example)?
  2. Output the combination with any given number (given 1, return ABC; given 5, return ACE and so on) in at worst O(M+N)?

It's trivial to do those things with O(M^N) complexity by generating the whole list, but I wonder if there's a better solution.

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2 Answers 2

up vote 1 down vote accepted

The answer to the first question is straightforward: it is C(n,r), where we are to choose all combinations of r items from a set of size n. The formula is here among other places:

C(n,r) = n! / (r! (n-r)!)

The ability to select the i'th combination without computing all the others will depend on having an encoding that relates the combination number i to the combination. That would be much more challenging and will require more thought ...

(EDIT)

Having given the problem more thought, a solution looks like this in Python:

from math import factorial

def combination(n,r):
    return factorial(n) / (factorial(r) * factorial(n-r))

alphabet = "ABCDEFGHIJKLMNOPQRSTUVWXYZ"

def showComb(n,r,i,a):
    if r < 1:
        return ""
    rr = r-1
    nn = max(n-1,rr)
    lasti = i
    i -= combination(nn,rr)
    j = 0
    while i > 0:
        j += 1
        nn = max(nn-1,1)
        rr = min(rr,nn)    # corrected this line in second edit
        lasti = i
        i -= combination(nn,rr)
    return a[j] + showComb(n-j-1,r-1,lasti,a[(j+1):])

for i in range(10):
    print(showComb(5,3,i+1,alphabet))

... which outputs the list shown in the question.

The approach I've used is to find the first element of the i'th output set using the idea that the number of combinations of the remaining set elements can be used to find which should be the first element for a given number i.

That is, for C(5,3), the first C(4,2) (=6) output sets have 'A' as their first character, then the next C(3,1) (=3) output sets have 'B' then C(1,1) (=1) sets have 'C' as their first character.

The function then finds the remaining elements recursively. Note that showComb() is tail-recursive so it could be expressed as a loop if you preferred, but I think the recursive version is easier to understand in this case.

For further testing, the following code may be useful:

import itertools

def showCombIter(n,r,i,a):
    return ''.join(list(itertools.combinations(a[0:n],r))[i-1])

print ("\n")

# Testing for other cases   
for i in range(120):
    x = showComb(10,3,i+1,alphabet)
    y = showCombIter(10,3,i+1,alphabet)
    print(i+1,"\t",x==y,"\t",x,y)

... which confirms that all 120 examples of this case are correct.

I haven't calculated the time complexity exactly but the number of calls to showComb() will be r and the while loop will execute n times or fewer. Thus, in the terminology of the question, I am pretty sure the complexity will be less than O(M+N), if we assume that the factorial() function can be calculated in constant time, which I don't think is a bad approximation unless its implementation is naive.

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Looks great! I've been tinkering with your solution and tried to change the loop to for i in range(120): print(showComb(10,3,i+1,alphabet)). It produces wrong combinations and crashes though. –  dragonroot Mar 31 '13 at 23:43
    
@dragonroot: Thanks for the testing! Yes, there was a bug in the code that showed up when n-r was larger than 2. I've corrected it in the edited answer above. –  Simon Apr 1 '13 at 1:26
    
Works perfect now! –  dragonroot Apr 1 '13 at 3:19

Agree the first part is easy, put a similar equation to this into a language of your choice.

x=12
y=5
z=1
base=1
until [[ $z -gt y ]]
do
 base=`echo $x $z $base|awk '{print ($1/$2) * $3}'`
 x=`expr $x - 1`
 z=`expr $z + 1`
 echo base:$base
done

echo $base

The above example uses 12 Items, arranged in sets of 5 for 792 combinations.

To do the second part of your question... I am just thinking about it, but it is not straight forward by any stretch.

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